The present invention relates to an electric switch for an opening of an automobile, such as a side door, a rear trunk lid or rear tailgate.
The electric switch provokes the opening of the door, after having released the lock through the corresponding closure; manually or activated with the vehicle opening remote control or hands-free vehicle owner recognition system.
Electric switches for opening automobile openings are known that comprise a module, sealed by a membrane and provided with means for mounting on the frame of a side door or rear door of a vehicle. Inside the module there is a lever for, actuating a microswitch positioned under the membrane. This lever can be displaced between two positions, a rest position in which it is separated from said microswitch, and a switching position in which it is in contact with said microswitch when the user presses on the membrane. The lever returns to its initial rest position when the pressure ceases, the triggering of said microswitch resulting in the opening of the lock.
The microswitch is connected to metallic terminals. A sealing cover can be molded over the assembly formed by the microswitch and the terminals soldered to it. The cover overmolding process is completed during a high-pressure overinjection step.
However, a large percentage of switches have to be rejected during manufacture because of the high pressure of the injection process. The flow of injected polymer fractures the connection of the tabs of the microswitch with the terminals. Furthermore, the microswitch may be broken during the process.
To obtain a correct overinjection, parameters such as the pressure, the temperature and the dosage therefore have to be finely controlled to avoid damaging the switch.
Furthermore, a large percentage of switches are rejected during manufacture because of the poor position of the assembly formed by the microswitch and the terminals soldered to it at the moment of closure of the mold during the overmolding process. Consequently, the switches lose their water-tightness and their operating integrity.
Furthermore, the seal is not always sufficiently guaranteed at other points of the switch, thus providing ingresses for moisture from outside the vehicle that can damage the electric circuits.
The present invention therefore aims to at least partially resolve the problems of the prior art by proposing a robust electric switch, having a better seal-tightness and an enhanced method for manufacturing said switch.
To this end, the subject of the invention is an electric switch for a door or rear tailgate of an automobile, comprising:
The overmolded peripheral seal mounted astride the two electric and mechanical subassemblies makes it possible to easily obtain an entirely sealed switch. In other words, this overmolding of the seal attaches and entirely seals two subassemblies respectively containing mechanical and electric elements. The electric switch is thus made seal-tight to water or moisture from outside the vehicle or from outside the trim of the switch. This robust arrangement allows for the overmolding of the joining area of the two subassemblies without prejudicing the elements contained in the subassemblies with a good level of seal-tightness.
According to one or more characteristics of the electric switch, taken alone or in combination,
Also the subject of the invention is a method for manufacturing an electric switch for a rear door or tailgate of an automobile as described previously, characterized in that said electric and mechanical subassemblies are assembled before placing them in a mold to form said seal molded over said joining area between said mechanical and electric subassemblies.
It is also possible to overmold the cover and said elastic membrane during the overmolding of said seal.
Other advantages and features will become apparent from reading the description of the invention, and the following figures in which:
a is a cross-sectional view in the plane (Y, Z) of the electric switch of
b is a cross-sectional view in the plane (X, Z) of the electric switch of
a is a longitudinal cross-sectional view of an electric switch according to a third embodiment,
b is a perspective view of a reinforcing member of the electric switch of
a is a side perspective view of a guiding and holding case including an overmolded spring of an electric switch according to a fifth embodiment, and
b is a front perspective view of the guiding case of
In all the figures, the identical elements are given the same reference numbers.
The support 2 can be arranged above the fender in the case of a rear trunk lid electric switch, for example in a top portion of an extension of the plastic part of the fender.
The support 2 includes a through recess in which the electric switch 1 is fixed, for example by snap-fitting, such that a control button 3 of the electric switch 1 is accessible to a user from outside the vehicle and that a connector 4 of the electric switch 1 can be linked to the electric circuits arranged inside the vehicle. The control button 3 is, for example, positioned such that it is flush with the fender of the automobile at the level of the brand name of the automobile. Provision can also be made for the electric switch 1 to have a trim 5 on the outside of the opening, encircling the accessible part of the control button 3.
The electric switch 1 provokes the opening of the door, after having released the lock through the corresponding closure; manually or remotely activated with the vehicle opening remote control or hands-free vehicle owner recognition system.
A first embodiment of the electric switch 1 is shown in
The electric switch 1 has an electric subassembly 6 comprising a microswitch 7 and a mechanical subassembly 8 comprising activation means for said microswitch 7 (
The electric subassembly 6 comprises a casing having a tubular axial recess for the insertion of said activation means, said recess ending with the electric connector 4 inside which are housed the electric terminals of the microswitch (
The mechanical subassembly 8 includes a sheath 10 having, for example, a substantially tubular central opening in which are mounted the activation means for said microswitch.
The activation means comprise, for example, the control button 3 and an actuation lever 11 for said microswitch 7 fixed to said control button 3. The actuation lever 11 is, for example, fixed by snap-fitting to said control button 3. To this end, the control button 3 includes, for example, a central section opposite to a tactile actuation surface, that is inserted into a corresponding recess of said actuation lever 11 and side elastic fixing tabs each having an orifice coupling with a corresponding protuberance borne by the corresponding end of said actuation lever 11 (see, for example,
The actuation lever 11 is positioned axially to the microswitch 7 and it can be displaced between two positions, a rest position, in which it is separate from said microswitch 7, and a switching position (see
Provision is made for the actuation lever 11 to include an actuation axis 13 housed in a guiding and holding case 14 for the actuation lever 11.
The guiding case 14 has, for example, an internal tubular through-recess for receiving the actuation axis 13 and has an outer surface cooperating with the tubular opening of the sheath 10 and an inner recess of the electric subassembly 6, to maintain and guide the actuation axis 11 in its actuation, particularly in case of excessive actuation forces on the part of the user.
The electric 6 and mechanical 8 subassemblies also include cooperating assembly means for fixing said subassemblies 6, 8 together and the electric switch 1 also includes a seal 15 molded over the joining area between said mechanical 8 and electric 6 subassemblies.
The mechanical subassembly 8 and the electric subassembly 6 are, on the one hand, assembled in the joining area by shape cooperation. The interstices between the two subassemblies 6, 8 are then reduced.
For example, and as represented in
Also, the assembly means include fixing means, for example housed inside said electric switch 1. The fixing means are then protected from the external environment of the switch 1.
The fixing means can be produced by snap-fitting. To this end, the sheath 10 includes, for example, an annular holding hook 17 in the tubular opening, cooperating with teeth of corresponding snap-fitting arms 18 borne by the casing of the electric subassembly 6.
At the moment of assembly, the mechanical subassembly 8 is then assembled with the electric subassembly 6 by inserting the actuation lever 11 inside the tubular axial recess of the casing of the electric subassembly 6. The snap-fitting arms 18 of the casing are attached to the corresponding annular hook 17 of the sheath 10, and the peripheral edges 16a, 16b of the casing and of the sheath 10 are joined in the joining area. The joining area is then overmolded.
The overmolded peripheral seal 15 mounted straddling the two electric 6 and mechanical 8 subassemblies makes it possible to easily obtain an entirely sealed electric switch 1. In other words, this overmolding of the seal 15 attaches and entirely seals two subassemblies respectively containing mechanical and electric elements. The electric switch 1 is thus made seal-tight to water or moisture from outside the vehicle or from outside the trim of the switch. This robust arrangement allows for the overmolding of the joining area of the two subassemblies 6, 8 without prejudicing the elements contained in the subassemblies 6, 8, with a good level of seal-tightness.
Provision is made, for example, for said seal 15 to be in the form of a generally square frame, topping the protruding peripheral edges 16a, 16b.
The plastic used for the overmolding is a “soft” plastic. It comprises, for example, a thermoplastic material, such as an elastomer TPE-S. The bodies of the electric 6 and mechanical 8 subassemblies, such as the casing, the sheath 10, the activation means, are molded from a “hard” plastic, for example polypropylene.
The elastomers offer the advantage of strongly adhering to the hard plastics, such as polypropylene, which consequently makes it possible to obtain a good seal. Furthermore, the pressures used for the injection machines are lower, which reduces the risks of deterioration of the switch during manufacture.
The activation means also include an elastic return means for returning said actuation lever 11 to the initial rest position when the pressure ceases.
The activation means also include an overmolded flexible membrane 19, positioned around the actuation lever 11 of the activation means. The flexible membrane 19 is molded over the sheath 10 of said mechanical subassembly 8. The plastic used for the overmolding is also a “soft” plastic, such as, for example, a thermoplastic material, such as an elastomer TPE-S. The flexible membrane 19 allows the axial movement of the actuation lever 11.
The electric subassembly 6 may also include a cover 20 partially overmolding the connectors of said microswitch 7. The cover 20 is thus positioned axially to the microswitch 7 and to the actuation lever 11, at the rear of said microswitch 7 from where the connectors leave. The plastic used for the overmolding is also a “soft” plastic, such as, for example, a thermoplastic material, such as an elastomer TPE-S.
When a user presses on the button, it provokes the displacement of the actuation lever 11, which in turn activates the microswitch 7 by closing the electric circuit, which makes it possible to open the door or the trunk lid of the vehicle. Once the user stops exerting the pressure, the elastic return means displace the control button 3 and the activation lever 11 to their initial positions.
A second embodiment of the electric switch 1 is represented in
The difference lies in the fact that the activation means do not include any control button but a control membrane 21 overmolded at the end of the sheath 10 and at the end of the actuation lever 11. The control membrane 21 is intended to be received in the support 2 so as to be accessible to a user from outside the vehicle to activate the actuation lever 11.
A third embodiment of the electric switch 1 is represented in
The difference lies in the fact that the mechanical subassembly 8 and the electric subassembly 6 have protruding peripheral edges 22a, 22b respectively having a recess in which a metallic reinforcing member 23 is received. The metallic reinforcing member 23 is, for example, made of steel. It has, for example, a circular central orifice and a substantially square-shaped outer peripheral contour (see
A fourth and a fifth embodiment of the electric switch 1 are respectively represented in
The elastic return means comprises a spring positioned between the microswitch 7 and the guiding case 14 of the actuation lever 11.
According to the fourth embodiment represented in
According to the fifth embodiment represented in
The second end 28 of the overmolded spring 26 has, for example, an annular form, that can be positioned around said microswitch 7.
This variant makes it possible to reduce the manufacturing costs.
The method for manufacturing the electric switch 1 comprises the following succession of steps.
The bodies of the electric and mechanical subassemblies are manufactured, for example from a hard plastic molding in a first mold.
Then, said electric and mechanical subassemblies are assembled, for example by snap-fitting, before placing them in another mold and the joining area is overmolded with a soft plastic to form said seal 15 molded over said joining area between said mechanical 8 and electric 6 subassemblies. It is also possible to overmold the cover 20 and said elastic membrane 19 from said same soft plastic in the same step on the assembly line, which reduces the manufacturing costs.
The overmolding is carried out using a conventional plastic injection machine with lower pressures than those recommended by the usage standards.
The electric switch 1 obtained in this way is therefore more robust and exhibits a very high degree of seal-tightness. Furthermore, the manufacturing method makes it possible to reduce the number of rejected parts and is less costly.
Generally, said mechanical subassembly comprises activation means that can be displaced between two positions, a first rest position and an active position.
According to the embodiment described previously, the rest position consists in said idle activation means being maintained at a distance from said microswitch and the active position is a switching position in which they are in contact with said microswitch.
According to another embodiment, the activation means may be in contact whether the microswitch is in the on or off state.
According to another alternative, the electric switch includes at least one intermediate element between the microswitch and the activation means, this intermediate element belonging to the electric subassembly and/or to the mechanical subassembly.
Number | Date | Country | Kind |
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09380115 | Jun 2009 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/057831 | 6/4/2010 | WO | 00 | 4/13/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/139786 | 12/9/2010 | WO | A |
Number | Name | Date | Kind |
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4803320 | Lupoli et al. | Feb 1989 | A |
4839483 | Doyle | Jun 1989 | A |
5008505 | Takano et al. | Apr 1991 | A |
6744345 | Korczynski et al. | Jun 2004 | B2 |
Number | Date | Country |
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0 552 591 | Jul 1993 | EP |
Entry |
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International Search Report w/translation from PCT/EP2010/057831 dated Oct. 1, 2010 (4 pages). |
Number | Date | Country | |
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20120186954 A1 | Jul 2012 | US |